Post on 29-Sep-2020
April 3, 2006 NASA Goddard Space Flight Center
Melanie N. OttNASA Goddard Space Flight Center
USA, melanie.ott@gsfc.nasa.gov
misspiggy.gsfc.nasa.gov/photonics
Space Flight Requirements for Fiber Optic Components; Qualification Testing
and Lessons Learned
Reliability of Optical Fiber Components, Devices, Systems and
Networks III, Conf. 6193
April 3, 2006 NASA Goddard Space Flight Center
Outline• Introduction• NASA COTS Photonics Validation Approach• Construction Analysis• Vacuum Validation• Vibration Parameters• Thermal Parameters• Radiation Parameters• Lessons Learned-Manufacturing• Prequal Example: LRO• Conclusion
April 3, 2006 NASA Goddard Space Flight Center
Contributing ColleaguesCode 562: Parts, Packaging, & Assembly Technologies Branch
Dr. Xiaodan “Linda” Jin, Richard Chuska
Patricia Friedberg, Mary Malenab
Adam Matzuseski
April 3, 2006 NASA Goddard Space Flight Center
Introduction
Changes to the Mil-Spec system, NASA relied heavily.Telecommunications products available, state-of-the-art.Vendors and parts rapidly changing.Most photonics now COTS.Qualification not only impossible but far too expensive.Characterization of COTS for risk mitigation.Quality by similarity where possible.
Changes in Our GSFC EnvironmentShort term projects, low budgetsInstruments like GLAS, MLA, VCL, LOLA
April 3, 2006 NASA Goddard Space Flight Center
Issues to Consider
• Schedule, shorter term• Funds available,• Identify sensitive or high risk components.• System design choices for risk reduction.• Packaging choices for risk reduction.• Quality by similarity means no changes to part or
process.• Qualify a “lot” by protoflight method—you fly the
parts from the lot qualified, not the tested parts.• Telcordia certification less likely now.
April 3, 2006 NASA Goddard Space Flight Center
COTS Technology Assurance Approach For Space Flight
System Requirements (Instrument System Engineer) : Define critical component parameters and the quantity by how each can deviate from optimal performance as a result and during testing -- Performance requirements.Environmental Requirements (Mechanical, Thermal, Radiation Engineers)
Contamination and materials requirements.Box level random vibration, double for componentThermal environment, 10 C higher at extremesRadiation, worst case conditions.
Failure Modes Study, (Components Engineer)• Conditions and Parameters,
Test Methods• Tailored to capturing the largest amount of failure modes while testing for
space environment.
Test Plan• Contains necessary testing for mission while monitoring for failure modes.
April 3, 2006 NASA Goddard Space Flight Center
COTS Technology Assurance Approach
* Photonic Components for Space Systems, M. Ott, Presentation for Advanced Microelectronics and Photonics for Satellites Conference, 23 June 2004.
Flow chart courtesy of Suzzanne Falvey, Northrup Grumman, based on M Ott reference:
April 3, 2006 NASA Goddard Space Flight Center
Qualification PlanDefine critical parameters that must be stable during testing.Define acceptable changes in performance parameters as a final result of testing and testing (dynamic and permanent). Acceptance criteriaChoose parts or system to be tested. How many samples (sample size) can you afford to test (considering time, equipment, materials)?Materials Analysis,
Outgas testing for anything unknown, take configuration into account.Packaging! Destructive Physical Analysis is crucial to formulation of testing plan
Vibration Survival and “Shock” (larger components) TestUse component levels as defined by system requirementsDefine parameters to monitor during testing
Thermal Cycling/Aging Test or Thermal Vacuum (depends on materials analysis)Define which parameters will indicate which failure modeMonitor those parameters during testing.
Radiation TestingAccelerated dose rate, extrapolation model use if possible, worst conditions
Addition tests based on specific mission requirements?
April 3, 2006 NASA Goddard Space Flight Center
COTS Space Flight “Qualification”
* Photonic Components for Space Systems, M. Ott, Presentation for Advanced Microelectronics and Photonics for Satellites Conference, 23 June 2004.
Flow chart courtesy of Suzzanne Falvey, Northrup Grumman, based on M. Ott reference:
April 3, 2006 NASA Goddard Space Flight Center
Construction/Materials Analysis
Destructive Physical AnalysisIdentify packaging issues
Gases analysis, hermetic?Materials identification,
Packaging: wirebonds, die attach materialsIdentify non metallic materials for vacuum exposure
Potential contamination issues.
Construction Analysis is crucial!Long Term Reliability Will it survive harsh environments?
April 3, 2006 NASA Goddard Space Flight Center
Environmental Parameters
• Vacuum requirements– ( Materials Analysis or Vacuum Test or both)
• Vibration requirements• Thermal requirements• Radiation requirements
April 3, 2006 NASA Goddard Space Flight Center
Environmental Parameters: VacuumVacuum outgassing requirements:
- ASTM-E595, 100 to 300 milligrams of material125°C at 10-6 Torr for 24 hoursCriteria: 1) Total Mass Loss < 1%
2) Collected Volatile Condensable Materials < 0.1% - Configuration test- Optics or laser nearby, is ASTM-E595 enough?
-ask your contamination expert
1) Use approved materials2) Preprocess materials, vacuum, thermal 3) Decontaminate units: simple oven bake out, or vacuum?4) Vacuum test when materials analysis is not conducted and depending
on packaging and device. Space environment; vacuum is actually 10-9 torr, best to test as close as possible for laser systems. Many chambers don’t go below 10-7 torr.
April 3, 2006 NASA Goddard Space Flight Center
Launch vehicle vibration levels for small subsystem (established for EO-1)
Frequency (Hz) Protoflight Level20 0.026 g2/Hz20-50 +6 dB/octave50-800 0.16 g2/Hz800-2000 -6 dB/octave2000 0.026 g2/HzOverall 14.1 grms
However, this is at the box level, twice the protoflight vibration values establish the correct testing conditions for the small component.
Environmental Parameters: Vibration
April 3, 2006 NASA Goddard Space Flight Center
Environmental Parameters: Vibration
Frequency (Hz) Protoflight Level20 0.052 g2/Hz20-50 +6 dB/octave50-800 0.32 g2/Hz800-2000 -6 dB/octave2000 0.052 g2/HzOverall 20.0 grms
Launch vehicle vibration levels for small component(based on box level established for EO-1) on the “high” side.
3 minutes per axis, tested in x, y and z
April 3, 2006 NASA Goddard Space Flight Center
Environmental Parameters: ThermalThere is no standard, typical and benign –25 to +85 C.Telcordia is –45°C to +80°C.
Depending on the part for testing;Insitu testing where possible Add 10°C to each extreme for box level survival
Thermal cycles determined by part type60 cycles for assemblies for high reliability 30 cycles minimum for assemblies, high risk100 or more, optoelectronics. More for high power systems
Knowledge of packaging and failure modes really helps with cycles determination.
April 3, 2006 NASA Goddard Space Flight Center
Environmental Parameters: Radiation
LEO, 5 – 10 Krads, SAAMEO, 10 –100 Krads, Van Allen beltsGEO, 50 Krads, Cosmic Rays
Assuming 7 year mission,Shielding from space craft
Proton conversion to Total Ionizing Dose (TID)At 60 MeV, 1010 protons/Krad for silicon devicesFor systems susceptible to displacement damage
Testing for displacement damage: 3 energies in the range ~ 10 to 200 MeV. If you have to pick one or two energies stay in the mid range of 65 MeV and lower. Less probability of interaction at high energies. Ballpark levels: 10 –12 p/cm2 LEO, 10-13 p/cm2 GEO, 10-14 p/cm2 for special missions (Jupiter).
April 3, 2006 NASA Goddard Space Flight Center
Environmental Parameters: RadiationTypical space flight background radiation total dose30 Krads – 100 Krads over 5 to 10 year mission.
Dose rates for fiber components:• GLAS, 100 Krads, 5 yr, .04 rads/min• MLA, 30 Krads, 8 yr, .011 rads/min (five year ave)• EO-1, 15Krads, 10 yr, .04 rads/min
Any other environmental parameters that need to be considered?For example, radiation exposure at very cold temp, or prolonged
extreme temperature exposure based on mission demands.
April 3, 2006 NASA Goddard Space Flight Center
International Space Station 2000
Failure Analysis: Optical Fiber Cable 1999-2000
Fiber Optic Cable “Rocket Engine” DefectsHermetic coating holes,Polyimide coating holds waterFluorine generated during extrusion of bufferHollow tube construction
water and fluorine interaction results in HF acidHF etches pits into fiber getting through holes in coatingEtch pits deep into the core caused losses and cracks
Bad Combination
JacketStrength Members
Coating
Glass Fiber
BufferHermetic Seal
Lessons Learned
April 3, 2006 NASA Goddard Space Flight Center
Lessons Learned - TerminationsEpoxy curing schedules for space flight applications
high cure temperatures for terminations =failures at lower temperature operation
Germanium doped graded-index multimode is very sensitiveConstrained CTE = micro-crack propagation
Germanium doped graded index• Atomic structure stress• Concentration higher at core—CTE differences along cross section.• Micro-cracks exist, internal structure and manufacturing.
April 3, 2006 NASA Goddard Space Flight Center
Lessons Learned -TerminationsPolishing Processes
GSFC uses nothing larger than 5 micron lapping film.Using too high of a grit on the lapping film can set up latent cracks.
Inspection and CleaningGSFC uses 200 X final inspection.For especially Ge-doped Graded index fiber, avoid contamination
SEM images of contamination – Corrosion on fiber end face
April 3, 2006 NASA Goddard Space Flight Center
Lunar Orbiter Laser AltimeterLOLA
Receiver Telescope mounted on HGA and a fiber array to route signal from HGA to LOLA
Deployable HGA will move in x and y via gimbalsFiber bundle will be routed through gimbals, down boom and to LOLAIssues: Cold temperature during gimbal movement, low loss requirements
HGAS
Lunar Recon Orbiter : Laser Ranging and Altimetry
April 3, 2006 NASA Goddard Space Flight Center
LRO Ranging and Altimetry Test
Gimbals Window inside gimbal; RF cable wrap Window inside gimbal; Flexlite MLA cable wrap inside gimbal
Fiber optic cable (4 m) gimbal test inside of thermal chamber monitored in situ @ 850 nmEach gimbal cycle up and back is 4 min 45 sec
Cable wrapped through twice, in constant motion to 5000 cycles per temp for 3 temps;0°C, -10°C and -20°C
April 3, 2006 NASA Goddard Space Flight Center
LRO Ranging and Altimetry Gimbal Test
Results of Test 1 at 0°C, Last few gimbal cycles, flex losses < 0.010 dB
Gimbal Positions and Optical Insertion LossFrom 5590 to 5596 cycles at 0 degrees C
(Note: The fiber is tight at 0 position and loose at 180)
-0.012
-0.010
-0.008
-0.006
-0.004
-0.002
0.000
0.002
1/9/06 9:02 AM 1/9/06 9:07 AM 1/9/06 9:12 AM 1/9/06 9:17 AM 1/9/06 9:22 AM 1/9/06 9:27 AM
Date & Time
Inse
rtion
Los
s [d
B]
0
20
40
60
80
100
120
140
160
180
200
Gim
bal P
ositi
ons
[deg
ree]
Optical Insertion Loss
Gimbal Positions
April 3, 2006 NASA Goddard Space Flight Center
LRO Ranging and Altimetry Test
Results of Test 2 at -10°C, Last few gimbal cycles, flex losses < 0.012 dB
Gimbal Positions and Optical Insertion Loss@-10C with 5580 to 5586 cycles
(Note: The fiber is tight at 0 degrees position and loose at 180 degrees)
-0.012
-0.010
-0.008
-0.006
-0.004
-0.002
0.000
0.002
2/10/06 9:38AM
2/10/06 9:43AM
2/10/06 9:48AM
2/10/06 9:53AM
2/10/06 9:58AM
2/10/06 10:03AM
2/10/06 10:08AM
Date & Time
Inse
rtion
Los
s [d
B]
020406080100120140160180200
Gim
bal P
ositi
ons
[deg
ree]
Optical Insertion Loss
Gimbal Positions
April 3, 2006 NASA Goddard Space Flight Center
LRO Ranging and Altimetry Test
Results of Test 3 at -20°C, Last few gimbal cycles, flex losses < 0.012 dB
Gimbal Positions and Optical Insertion Loss@-20C From 1574 to 1580 cycles
(Note: The fiber is tight at 0 position and loose at 180)
-0.014
-0.012
-0.010
-0.008
-0.006
-0.004
-0.002
0.000
0.002
2/16/069:36 AM
2/16/069:41 AM
2/16/069:46 AM
2/16/069:51 AM
2/16/069:56 AM
2/16/0610:01 AM
2/16/0610:06 AM
Date & Time
Inse
rtion
Los
s [dB
]
0
20
40
60
80
100
120
140
160
180
200
Gim
bal P
ositi
ons
[deg
ree]
Optical Insertion LossGimbal Positions
April 3, 2006 NASA Goddard Space Flight Center
Mercury Laser Altimeter and Homer Make News
A laser communication link established (MLA to NASA GSFC)24 million kilometres (15 million miles),
Messenger (Mercury Laser Altimeter) spacecraft and the HOMER Laser (by D. Barry Coyle) at the GSFC ground station.
Transmitted pulses back and forth to each otherNo actual information was transmitted but….Experiment shows the potential for interplanetary laser links
Read the article in New Scientist Space, Jeff Hecht, Jan 2006
April 3, 2006 NASA Goddard Space Flight Center
ConclusionPerformance Requirements (System Engineer, Top level Spec)Environmental Requirements
Thermal EngineerContamination EngineerRadiation Physicist
Physics of Failure--Materials Analysis (crucial!)Components EngineerMaterials Experts
Test Plan tailored to above, Define criteria or range of performance allowable.Quality by similarity for environmental testing.
Choose Telcordia qualified when you can, plan additional testing.
April 3, 2006 NASA Goddard Space Flight Center
Thank you for the invitation!
For more information please visit the website:http://misspiggy.gsfc.nasa.gov/photonics
1) Qualification and Issues with Space Flight Laser Systems and Components, M. Ott, D. B. Coyle, J. Canham, H. Leidecker, Jan 26, 2006 SPIE Photonics West, Vol. 6100.
3) SPIE Optics and Photonics Conference, Aug 2006 USAAtmospheric and Space Optical Systems and InstrumentationPhotonics for Space Environments XI
• Current Activities in the Photonics Group at NASA GSFC• Qualification of MTP and Ribbon Cable Assemblies for Space
(with Sandia National Labs)
2) ESA-NASA Workshop-LIDAR Optoelectronics for Space, June 2006 at ESTEC, Netherlands (Dr. Nikos Karafolas & Melanie Ott)